Eye protection device for welding helmets

ABSTRACT

Light transmission control device includes band pass filter for transmitting light of a wavelength or group of wavelengths and partially blocking transmission of light of a different wavelength or group of wavelengths, and variable optical filter for controllably transmitting light of a wavelength or group of wavelengths, the band pass filter and variable optical filter being cooperative to provide at least three light transmitting modes, including maximum transmission, minimum transmission, and a third mode less transmissive than the maximum, the device being operative to minimum transmissive mode upon being driven by a maximum energy input, the device also being operative to maximum transmissive mode upon being driven by a lesser energy input, and such third transmission mode occurring in response to no power or a failure of power or adequate power for energizing the device to the maximum or minimum transmissive mode.

TECHNICAL FIELD

The present invention relates generally, as is indicated, to the control of transmission of electromagnetic energy, especially for controlling transmission of light, and, more particularly, the present invention relates to improvements for automatically controlling light transmitted through a lens in an eye protection device, such as a welding helmet or the like.

According to one embodiment, the invention relates to such a lens and welding helmet which has both a rapid driven to dark state during which eye protection is provided during welding, a clear state during which maximum clarity is provided for viewing through the lens when welding is not occurring, and a fail state that provides a dark condition for eye protection, for example, if lens power were to fail during welding.

BACKGROUND

Welding helmets have been used in the past to protect the eyes and face of a person doing welding (hereinafter referred to as a welder) from the very bright light occurring during welding, e.g., emanating from the welding arc, and from possible particles that may be flung toward the welder during welding. Early welding helmets had a lens through which a welder would view the work being welded and a protective shield material, such a metal, plastic or other solid material, that contained the lens and protected the welder's face from the light emitted by the welding operation and from particles. Typically the lens was a material that would transmit a relatively small amount of the incident light and, thus, when the welding was occurring would permit enough light to pass to the welder's eyes to observe the welding operation while blocking a substantial amount of the light occurring during welding so that the eyes would not be injured. Sometimes the lens was used in spectacle frames for eye protection without the face protecting shield.

Early welding helmets suffered from the disadvantage that the lenses were of fixed light transmission characteristic, i.e., darkness. Since the lenses were adequately dark (non-transmissive of or able to block transmission of some light) to perform eye protection function, it was difficult or even impossible in the absence of the welding arc to see through the lens such as to start a welding torch, arc, etc.

Efforts were made to provide variable light transmission characteristics in welding lenses and/or in welding helmets using such lenses. Several examples included variable mechanical devices, such as mechanical shutters located over the viewing area of the welding helmet to control the aperture through which light may be transmitted to the eyes of the welder. Sensors detected the occurrence of the welding light and caused a circuit automatically to close the shutter aperture.

Another early mechanical shutter used relatively rotatable polarizers in optical series. Depending on the brightness or "clearness" desired (or darkness or light attenuation desired) one polarizer was rotated relative to the other. A sensor for detecting incident light and a circuit responsive to the sensor controlled the relative rotation of the polarizers.

An example of a variable solid crystal welding lens with polarizers in protective eye glasses (spectacles) or goggles is disclosed in Marks et al. U.S. Pat. No. 3,245,315.

Other efforts made to provide variable light transmission characteristics for a welding lens have used variable liquid crystal light shutter devices. Two examples of twisted nematic liquid crystal cells used in welding lens assemblies in welding helmets are disclosed in U.S. Pat. Nos. Re. 29,684 (Gordon) and 4,039,254 (Harsch). In Gordon light shutter a twisted nematic liquid crystal cell, sandwiched between crossed polarizers, rotates the plane of polarized light received from one polarizer to pass it through the second polarizer, thus allowing a welder to see in the absence of a welding arc. In response to welding light being detected by a sensor, a circuit energizes the twisted nematic liquid crystal cell so that polarized light remains unrotated and crossed polarizers block light transmission. In Harsch minimum light transmission occurs in the deengergized (dark) state and maximum transmission occurs when the liquid crystal cells are energized (clear state). In Harsch three polarizers and two twisted nematic liquid crystal cells are arranged such that residual leakage of light through the upstream pair of polarizers and liquid crystal cell when minimum transmission is intended will be reduced by cooperation with the downstream liquid crystal cell and the further polarizer without substantially reducing transmission when in the clear (energized) state.

Alignment of three parallel directionally aligned polarizers and two twisted nematic liquid crystal cells (the five being arranged alternately in tandem to provide selective control of light transmission) also is disclosed in Fergason U.S. Pat. No. 3,918,796.

As is discussed further below, a problem encountered with prior automated welding lenses, especially liquid crystal lenses, is that they have only two operational states, a dark state and a clear state. If there were a power failure (no or too little power to the lens), the lens would fail to a predetermined state, either clear or dark. Due to characteristics of the twisted nematic liquid crystal cell, if failure were to the dark state, then speed is sacrificed; if failure were to the clear state, then eye protection upon occurrence of a power failure is sacrificed.

In such a twisted nematic liquid crystal cell, e.g., as is disclosed in U.S. Pat. Nos. Re. 29,684 and 4,039,254, nematic liquid crystal is located between a pair of generally flat plates which are pretreated at a respective surface of each by parallel rubbing or by some other process to obtain generally parallel structural alignment (alignment of the directors) of the liquid crystal material relative to the rub direction. The plates are placed in parallel to each other such that the rub direction of one surface is perpendicular to the rub direction of the other, and the liquid crystal material between the plates tends to assume a helical twist. During use, the twisted nematic liquid crystal cell is placed between a pair of plane polarizers (also referred to as linear polarizers). Light incident on the first polarizer is linearly polarized thereby and directed through the twisted nematic liquid crystal cell to the second polarizer. In the absence of an electric field input to the twisted nematic liquid crystal cell, the plane of polarization is rotated, for example, ninety degrees as the light is transmitted through the cell. Such light transmission through a twisted nematic liquid crystal cell sometimes is referred to as wave guiding of the light. In the presence of an electric field sufficient to cause alignment of substantially all of the liquid crystal material in the cell with respect to such field, the plane polarized light incident on the cell is transmitted therethrough without such rotation. Depending on the orientation of the second polarizer (also sometimes referred to as the analyzer or analyzer polarizer) relative to the first polarizer, polarized light will be transmitted or blocked, as a function of alignment of the liquid crystal material in the cell and, thus, of whether or not electric field is applied. The light transmission and the control of light transmission usually is substantially the same for any wavelength of the light.

A liquid crystal cell may be formed by a pair of generally parallel plates and liquid crystal material sandwiched therebetween, e.g., as in the several liquid crystal cells mentioned in this Background. However, it will be appreciated that a liquid crystal cell used in a welding lens or other device which embodies the principles or features of the invention alternatively may include several such liquid crystal cells in side by side relation to make up a larger area liquid crystal cell. Alternatively, other liquid crystal devices which perform functions similar and/or equivalent to those described for the liquid crystal cells herein also may be employed as a liquid crystal cell according to the invention.

Another type of liquid crystal light control device is known as a dyed liquid crystal cell. Such a dyed cell usually includes nematic liquid crystal material and a pleochroic dye that absorbs or transmits light according to orientation of the dye molecules. As the dye molecules tend to assume an alignment that is relative to the alignment of the liquid crystal structure or directors, a solution of liquid crystal material and dye placed between a pair of plates will absorb or transmit light depending on the alignment of the liquid crystal material. Thus, the absorptive characteristics of the liquid crystal device can be controlled as a function of applied electric field.

A surface mode liquid crystal cell, which is still another type of liquid crystal cell, and devices using such a cell are disclosed in U.S. Pat. Nos. 4,385,806, 4,436,376, Re. 32,521, and 4,540,243. In contrast to the wave guiding type operation of a twisted nematic liquid crystal cell, the surface mode liquid crystal cell operates on the principle of optical retardation, and, in particular, it operates to retard one of the two quadrature components (sometimes referred to as ordinary ray and extraordinary ray, respectively) of plane polarized light relative to the other. Thus, a surface mode liquid crystal cell effectively can rotate the plane of polarization of plane polarized light by an amount that is a function of a prescribed input, usually an electric field. A surface mode liquid crystal cell in effect is a variable optical retarder or variable wave plate that provides retardation as a function of the prescribed input.

Briefly, a surface mode liquid crystal cell is constructed of nematic liquid crystal (or liquid crystal that functions like nematic liquid crystal insofar as indices of refraction, birefringence, structural alignment, etc. characteristics are concerned) and a pair of generally parallel plates, each having been rubbed or otherwise treated at one surface thereof to effect desired alignment of the liquid crystal structure at the surfaces. The rub directions, for example, of the surfaces of the two plates forming the surface mode liquid crystal cell are parallel, i.e., generally in the same or opposite direction, to each other rather than at a right angle to each other (the case of the twisted nematic liquid crystal cell). Treatment also may provide for a tilt angle of the liquid crystal directors at the surfaces, as may be desired for various operational results, as is well known in the art.

The surface mode liquid crystal device may be wavelength sensitive in that the amount of retardation for a given set of conditions thereof is a function of the wavelength of the incident light. Depending on the birefringence of the liquid crystal material in a surface mode liquid crystal cell, the thickness of the layer of liquid crystal material in the cell, the magnitude of the applied prescribed input, usually electric field, when applied and the technique with which the surface mode liquid crystal cell is driven, the amount of retardation can be controlled or determined. These considerations and features are described in the above-mentioned U.S. patents related to surface mode liquid crystal cells and devices and in other literature.

In a surface mode liquid crystal cell that is positioned between a pair of plane polarizers, the amount of retardation of plane polarized light incident on the cell can be determined as a function of the aforementioned characteristics, including, as well, the wavelength of the incident light. In fact, depending on the wavelength makeup of the incident light, the effective thickness of the birefringent liquid crystal layer(s) in the cell, and the birefringence of that (those) layer(s), optical color dispersion may occur. (The principles of optical color dispersion, birefringence, optical polarization and polarized light are described in Fundamentals of Optics by Jenkins and White, McGraw-Hill Book Company, New York, 1976.) Moreover, depending on the plane of polarization of the output light transmitted through the cell and output therefrom and the relative directional orientation of the output plane polarizer (analyzer), the intensity of the transmitted light through the output plane polarizer may be varied. Therefor, if the surface mode cell is so constructed and so energized or operated that significant color dispersion does occur, then a color or wavelength filtering function can occur.

Further, a surface mode cell may be so constructed and so energized or operated that significant color dispersion does not occur. This type of operation occurs when the surface mode liquid crystal cell is operated at what is referred to as zero order, as is described in the four patents related to surface mode liquid crystal cells mentioned just above. In such operation intensity modulation of the light output from the cell can be achieved with substantial uniformity (so that there is no or only minimal distortion of the transmitted images) and without color dispersion so that the lens essentially is achromatic.

As will be described further below, the present invention is directed to a variable optical transmission controlling device which has at least three different output conditions. The device is described in detail with respect to use in a welding helmet. However, it will be appreciated that the device may be employed in other environments and in other devices and systems for controlling transmission of electromagnetic energy broadly, and, in particular, optical transmission. As used herein with respect to the preferred embodiment, optical transmission means transmission of light, i.e., electromagnetic energy that is in the visible spectrum and which also may include ultraviolet and infrared ranges. The features, concepts, and principles of the invention also may be used in connection with electromagnetic energy in other spectral ranges.

The invention is especially useful for eye protection wherein high speed protective shuttering and protective fail state are desired. Exemplary uses are in welding helmets, spectacles, goggles, and the like, as well as safety goggles for nuclear flash protection, for protection from hazards experienced by electric utility workers and for workers at furnace and electrical plant areas and at other places where bright light that could present a risk of injury may occur.

Further, the invention is described herein as undergoing certain operation in response to a prescribed input. The preferred prescribed input is an electric field. However, it will be appreciated that other prescribed inputs may be used, and reference to electric field may include equivalently such other prescribed inputs. For example, as is known, liquid crystal cells are responsive to magnetic field inputs and to thermal inputs. Other inputs also may be possible to obtain generally equivalent operation.

As is well known, the transition speed for a liquid crystal cell, whether of the twisted nematic type, dyed cell type or surface mode type, is asymmetrical; in particular, such a liquid crystal cell operates faster to achieve an operational condition, e.g., alignment of liquid crystal structure or directors, when driven to that condition by an electric field (or an increase in the field magnitude), than it operates when relaxing to a deenergized or reduced energization state, e.g., reduction or elimination of the electric field. Therefore, for maximum speed of operation to the dark state for eye protection, for example, it is desirable in a welding lens environment that the liquid crystal lens be operated with maximum power to achieve the darkest eye protection state. Also, a surface mode liquid crystal cell usually responds to energization significantly faster than a twisted nematic liquid crystal cell, and it, therefore, provides for faster operation in accordance with the present invention.

Shade number or shade is the characterization of darkness of a welding lens, for example, (hereinafter sometimes simply referred to as lens); a larger shade number represents a darker, more light blocking (or absorbing) or less optically transmissive lens and a smaller shade number represents a less dark, less light blocking (or absorbing) or more optically transmissive lens. Generally optical transmission means transmission of light and the image or view carried by the light without substantial distortion of those images, e.g., due to scattering. Shade number is a term of art often used in the field of welding and especially welding lenses for eye protection.

Clear state or clear shade means the state of highest operating luminous transmittance (or light transmission) of the lens. This state corresponds to the state having the lowest shade number for the lens.

Dark state or dark shade is the lowest operating luminous transmittance (or light transmission) of the lens. This state corresponds to the state having the highest specified shade number for the lens. The invention is described below in some instances indicating that in the dark state no light is transmitted. While this may be desirable for some applications of the principles of the invention, it will be appreciated that for a welding lens in the dark state there will be some transmission so that the welder can see to do the welding while some light is blocked to provide the desired eye protection from damage, injury or the like by the light emitted during welding.

Intermediate state or intermediate shade is one that is not the clear state and the dark state. It may be between the clear state and the dark state, but this is not always necessary, for it may even be darker than the dark state if such operation could be achieved. According to the described embodiment of the invention, the intermediate state provides an intermediate level of light transmission/absorption, i.e., between the clear state and the dark state, and occurs during power failure, inadequate power, or power off status of the lens.

Power failure, failure, or fail state means absence of power being delivered to the lens. Power failure also may mean that inadequate power is being delivered to the lens to cause it to assume the desired state.

Off state is the condition of the lens when no electrical power is being supplied to the lens; the off state also is referred to as the power-off state. As is described below, the intermediate shade preferably occurs in the welding lens during the off state. The fail state of the lens also is the off state, i.e., no power is provided due to failure of the power supply; and the fail state also may occur when there simply is inadequate power available to drive or to energize the lens to the clear state and dark state.

Shutter response time is the time required for the circuitry associated with the lens to detect a sharp increase in incident light (e.g., due to striking of the welding arc, etc.) and to switch the lens from the clear state to the dark state.

Shutter recovery time is the time required for the circuitry associated with the lens to detect a sharp decrease in light (e.g., due to extinguishing of the welding arc, etc.) and to switch the lens from the dark state to the clear state.

Variable transmittance is the ability of the lens to be switched from one level of luminous transmittance (also referred to as transmission of light) to another level of luminous transmittance in response to a change in incident illumination.

Dynamic operational range or dynamic optical range is the operational range of the lens between the dark state and the clear state, e.g., the difference between the shade numbers of the dark state and the clear state.

As was mentioned above, a problem encountered with prior automated welding lenses, especially liquid crystal lenses, is that they have only two operational states, a dark state and a clear state. If there were a power failure (no or too little power to the lens), the lens would fail to a predetermined state, either clear or dark. If failure were to the dark state, then speed is sacrificed; if failure were to the clear state, then protection upon occurrence of a power failure is sacrificed.

More specifically, it is known that alignment of liquid crystal material (or the directors thereof) occurs faster when energy is applied or is increased from a lower energization level compared to slower alignment due to relaxation or the like when energy is removed or reduced. Therefore, if the conventional twisted nematic liquid crystal lens, upon failure of the power supply, would fail to a dark state, such dark state would be the result of "relaxation" of the liquid crystal. Accordingly, the operation of the lens would be relatively slow in response to the commencing of welding and the bright light produced thereby, thus minimizing the protection for the welder. If failure were to the clear state, then the occurrence of power failure during (or at the inception of) welding would result in the lack of protection for the welder. Further, if two liquid crystal cells were arranged in optical series with appropriate polarizers, e.g., as in the above-mentioned Harsch patent, an intermediate darkness failure mode could be made possible by orienting one of the analyzer polarizers to transmit the plane polarized light received from its immediately optically upstream deenergized twisted nematic liquid crystal cell and the other analyzer polarizer to block the plane polarized light received from its immediately optically upstream twisted nematic liquid crystal cell. Then, for a dark state, one liquid crystal cell is energized and the other is deenergized; and for the clear state the opposite liquid crystal cell is energized and the other is deenergized. In this case a power failure would allow reduced light transmission due to the dark state of one of the twisted nematic liquid crystal cells (with its pair of polarizers), but the overall lens would suffer in reduced speed due to the needed relaxation time for the other liquid crystal cell when the lens is switched from clear state to dark state in order to achieve maximum darkness of the lens in response to inception of welding.

It would be desirable to provide an improved variable light transmission controlling device, especially one for use in welding helmets or the like, which provides both a clear state and a dark state as well as an intermediate state which in a failure mode, such as in the absence or inadequacy of power to the device, is darker than the clear state, e.g., so as to provide a temporary measure of eye protection and to minimize risk, or even is as dark or darker than the dark state. It would be further desirable to provide such characteristics while also providing fast operational speed for the light transmission controlling device in switching to the dark state, for example, by providing switching to the dark state as a powered or driven condition of the lens.

The entire disclosures of all of the above-mentioned patents and patent applications are hereby incorporated by reference.

BRIEF SUMMARY

Briefly, according to one aspect of the invention, a light transmission control device includes a band pass filter for transmitting light of a prescribed wavelength or group of wavelengths and for partially blocking transmission of light of a different prescribed wavelength or group of wavelengths, and a variable optical filter for controllably transmitting light of a wavelength or group of wavelengths that is a function of tuning, and wherein the band pass filter and variable optical filter are cooperatively related to provide at least three different light transmitting modes, including relatively maximum transmission, relatively minimum transmission, and a third mode that is less transmissive that the maximum transmissive mode.

As used herein, the term wavelength may mean either a specific wavelength of electromagnetic energy, such as light having a wavelength 550 nm, or a group of wavelengths, such as light falling within the group of wavelengths 550 nm to 600 nm, etc. Also, reference to one wavelength being different from another may mean that the specific wavelengths are different, e.g., as 550 nm wavelength light is different from 600 nm wavelength light; it also may mean that the collection of wavelengths of one group of wavelengths differs from that of another group of wavelengths; and it also may mean that if two groups of wavelengths have the same collection of wavelengths, the intensity or magnitude of a given wavelength of one group differs from the intensity or magnitude of that wavelength of the another group.

According to another aspect of the invention, a light transmission control device includes a band pass filter for transmitting light of a prescribed wavelength or group of wavelengths and for partially blocking transmission of light of a different prescribed wavelength or group of wavelengths, and a variable optical filter for controllably transmitting light of a wavelength or group of wavelengths that is a function of tuning, and wherein the band pass filter and variable optical filter are cooperatively related to provide at least three different light transmitting modes, including relatively maximum transmission, relatively minimum transmission, and a third mode that is less transmissive that the maximum transmissive mode, and wherein the device is operative to the minimum transmissive mode upon being driven in response to a relatively maximum energy input thereto.

According to still another aspect of the invention, a light transmission control device includes a band pass filter for transmitting light of a prescribed wavelength or group of wavelengths and for partially blocking transmission of light of a different prescribed wavelength or group of wavelengths, and a variable optical filter for controllably transmitting light of a wavelength or group of wavelengths that is a function of tuning, and wherein the band pass filter and variable optical filter are cooperatively related to provide at least three different light transmitting modes, including relatively maximum transmission, relatively minimum transmission, and a third mode that is less transmissive that the maximum transmissive mode, and wherein the device is operative to the minimum transmissive mode upon being driven in response to a relatively maximum energy input thereto, and wherein the device also is operative to the maximum transmissive mode upon being driven in response to a relatively lesser energy input thereto.

According to even another aspect of the invention, a light transmission control device includes a band pass filter for transmitting light of a prescribed wavelength or group of wavelengths and for partially blocking transmission of light of a different prescribed wavelength or group of wavelengths, and a variable optical filter for controllably transmitting light of a wavelength or group of wavelengths that is a function of tuning, and wherein the band pass filter and variable optical filter are cooperatively related to provide at least three different light transmitting modes, including relatively maximum transmission, relatively minimum transmission, and a third mode that is less transmissive that the maximum transmissive mode, and wherein the device is operative to the minimum transmissive mode upon being driven in response to a relatively maximum energy input thereto, and wherein the device also is operative to the maximum transmissive mode upon being driven in response to a relatively lesser energy input thereto, and wherein such third transmission mode occurs in response to there being now power or a failure of power or adequate power for energizing the device to the maximum or minimum transmissive mode.

Another aspect according to the invention is to accomplish the operation and functions herein described using at least one liquid crystal element, cell, or the like as an optical transmission control component of the device.

According to another aspect of the invention, a light transmission control device includes a band pass filter for transmitting light of a prescribed wavelength and for partially blocking transmission of light of a different prescribed wavelength, and a variable optical filter for controllably transmitting light of a wavelength that is a function of tuning, and wherein the band pass filter and variable optical filter are cooperatively related to provide at least three different light transmitting modes, including relatively maximum transmission, relatively minimum transmission, and a relatively intermediate transmission and wherein the variable optical filter is tuned by construction thereof for the intermediate transmission state so that in the absence of power the variable optical filter substantially blocks light of such prescribed wavelength and transmits at least some light at such different prescribed wavelength.

According to still another aspect of the invention, a light transmission control device includes a band pass filter for transmitting light of a prescribed wavelength and for partially blocking transmission of light of a different prescribed wavelength, and a variable optical filter for controllably transmitting light of a wavelength that is a function of tuning, and wherein the band pass filter and variable optical filter are cooperatively related to provide at least three different light transmitting modes, including relatively maximum transmission, relatively minimum transmission, and a relatively intermediate transmission and wherein the variable optical filter is tuned by construction thereof for the intermediate transmission state so that in the absence of power the variable optical filter substantially blocks light of such prescribed wavelength and transmits at least some light at such different prescribed wavelength, and wherein transmission is a function of a prescribed input such that at relatively maximum input there will be blocking of substantial portion of all light transmitted by the band pass filter and at reduced, but nevertheless existing, input there will be transmission of substantially all light transmitted by the band pass filter.

According to yet another aspect of the invention a lens assembly for protecting the eyes includes a band pass filter for transmitting light of a given wavelength and for blocking transmission of light of a different wavelength, and a liquid crystal device in optical serial relation with the band pass filter, the liquid crystal device having variable light transmitting conditions as a function of application of electric field thereto, the liquid crystal device being tuned for operation in the absence of an electric field to transmit some light and to block some light at the wavelength transmitted by the band pass filter, the liquid crystal device being responsive to application of an electric field of a first magnitude to be tuned to transmit substantially all light incident thereon, and the liquid crystal device being responsive to application of an electric field of a magnitude larger than the first to block transmission of substantially all light incident thereon.

According to a further aspect of the invention an apparatus for controlling transmission of electromagnetic energy which has a plurality of wavelengths and is incident thereon includes a band pass filter for transmitting at least some such electromagnetic energy incident thereon at at least one wavelength and for partially blocking (filtering) such electromagnetic energy at at least one wavelength, a controllable optical device in optical series with the band pass filter, the controllable optical device being able to assume at least three different operational modes including,

i. a first such mode providing substantial transmission of such electromagnetic energy transmitted by the band pass filter,

ii. a second such mode providing blocking (filtering) of a substantial portion of the electromagnetic energy transmitted by said band pass filter, and

iii. a third such mode providing at least partial blocking (filtering) of some of such electromagnetic energy at the wavelength partially blocked (filtered) by the band pass filter.

Still another aspect is to provide a liquid crystal variable light transmission controlling device, i.e., a device which includes a liquid crystal cell or similar component, which has three different shade capabilities, including the dark state, a clear state and an intermediate state, and wherein the device requires an electrical input to drive it to such dark and clear states.

Still a further aspect is to provide for three different shade capabilities in a variable light transmission controlling device, wherein there are substantially clear, substantially dark, and intermediate shade number capabilities, and wherein the intermediate shade capability occurs in the event of a power failure mode.

An aspect of the invention relates to controlling transmission of light energy which has a plurality of wavelengths incident thereon, by filtering light using a band pass filter for transmitting at least some of such light energy of least one wavelength and for filtering at least some of such light energy of at least one other wavelength, variably filtering such light by an electronically controlled variable optical filter for controllably transmitting light of a wavelength that is a function of tuning in response to a prescribed input thereto, and wherein in the absence of a prescribed input, the electronically controlled variable optical filter transmits at least some of such light energy incident thereon of at least one wavelength and filters at least some of such light energy of at least one wavelength and further wherein the optical filter is operative in the presence of a relatively small prescribed input to provide maximum transmission by the device, is operative in the presence of a relatively maximum prescribed input to provide minimum transmission by the device and is operative in the presence of a prescribed input at a level between the maximum and the minimum input levels to provide transmission by the device at a level between the maximum and the minimum transmission.

An aspect of the invention relates to controlling transmission of light energy which has a plurality of wavelengths incident thereon, by filtering light using a band pass filter for transmitting at least some of such light energy of least one wavelength and for filtering at least some of such light energy of at least one other wavelength, variably filtering such light by an electronically controlled variable optical filter for controllably transmitting light of a wavelength that is a function of tuning in response to a prescribed input thereto, and wherein in the absence of a prescribed input, the electronically controlled variable optical filter transmits at least some of such light energy incident thereon of at least one wavelength and filters at least some of such light energy of at least one wavelength and further wherein the optical filter is operative in the presence of a relatively small prescribed input to provide maximum transmission by the device, is operative in the presence of a relatively maximum prescribed input to provide minimum transmission by the device and by varying the prescribed input between the maximum and the minimum level will vary the transmission of the device.

Yet another aspect of the invention is to provide the various features disclosed and claimed herein in an eye protection device, and especially in a welding helmet (or goggles or spectacles or the like) for protecting the eyes of a welder, or the like.

To the accomplishment of the foregoing and related ends, the invention, then, comprises the features hereinafter fully described and particularly pointed out in the claims. The following description and the annexed drawings set forth in detail certain illustrative embodiments of the invention. These embodiments are indicative, however, of but a few of the various ways in which the principles of the invention may be employed.

Although the invention is shown and described with respect to certain preferred embodiments, it is obvious that equivalents and modifications will occur to others skilled in the art upon the reading and understanding of the specification. The present invention includes all such equivalents and modifications, and is limited only by the scope of the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

In the annexed drawings:

FIG. 1 is a schematic view of a welding helmet with a variable liquid crystal lens in accordance with the present invention;

FIG. 2 is a schematic view of the lens of FIG. 1;

FIG. 3 is a graph depicting the optical transmission characteristics of the band pass filter and the controllable variable wavelength transmission controlling device used in the lens of FIG. 2 to show the intermediate transmission state therof;

FIG. 4 is a graph depicting the optical transmission characteristics of the band pass filter and the controllable variable wavelength transmission controlling device used in the lens of FIG. 2 to show the clear transmission state thereof;

FIG. 5 is a schematic view of an embodiment of the lens of FIG. 2 using a pair of plane polarizers and a surface mode liquid crystal cell therebetween, directions of polarization and/or of axes of various optical elements are indicated by arrows pointing up indicating relatively vertical or angularly indicating at an angle relative to vertical and/or to horizontal, and/or by "X" indications representing direction into the plane of the paper, the same convention being employed in the other drawing figures;

FIG. 6A is a schematic view of a controllable variable wavelength transmission controlling device including a surface mode liquid crystal cell shown in the power off intermediate darkness state for use in the lens of the present invention;

FIG. 6B is a schematic view of the controllable variable wavelength transmission controlling device including a surface mode liquid crystal cell of FIG. 6A, but here shown in the clear state for use in the lens of the present invention;

FIG. 6C is a schematic view of the controllable variable wavelength transmission controlling device including a surface mode liquid crystal cell of FIGS. 6A and 6B, but here shown in the dark state for use in the lens of the present invention;

FIG. 7 is a schematic view of an embodiment of the lens of FIG. 2 using two liquid crystal stages and wherein at least one is a surface mode liquid crystal cell;

FIG. 8 is a schematic view of the preferred embodiment of the lens of FIG. 2 using two surface mode liquid crystal devices and a band pass filter;

FIG. 9 is a graph depicting operation of an embodiment of the lens of FIG. 8 in which the surface mode liquid crystal cells are tuned to cooperate with the associated polarizers to block light respectively at different wavelengths; and

FIG. 10 is a graph depicting the intensity of light transmitted by the lens of FIG. 8 as a function of the voltage of applied electric field as a prescribed input to the lens.

DETAILED DESCRIPTION

Referring, now, in detail to the drawings, wherein like reference numerals designate like parts in the several figures, and initially to FIG. 1, a welding helmet 1 according to the invention includes a protective shield 2 and a filter assembly 3 mounted in the shield. The shield 2 may be of generally optically non-transmissive material, such as metal, plastic, or other material to protect a welder's face and/or head as is conventional. The filter assembly 3 may be permanently mounted in an opening 4 of the shield 2, or means (not shown) may be provided to hold the filter assembly 3 in the opening 4 and also to permit removal of the filter assembly from the shield, if desired.

The filter assembly 3 itself includes a welding lens 5 and a driving circuit 6 for supplying a prescribed input to the welding lens 5 to effect operation. Preferably that input is an electric field produced by a voltage from the driving circuit 6 suitable to operate a liquid crystal cell in the welding lens, as is described further below. However, it will be appreciated that the prescribed input may be other than an electric field, for example, a magnetic field, thermal energy, or some other prescribed input that will operate the welding lens 5.

The welding lens 5 is of a type that can achieve three different optical states, namely a clear state, a dark state, and a third state (referred to below as an intermediate state) of optical transmission that is different from the clear state and the dark state. The intermediate state has a transmissive quality that is preferably darker than the clear state, and likely, but not necessarily, less dark than the dark states i.e., between the clear state and the dark state (as is described below in the illustrative examples of the invention). Moreover, the welding lens 5 preferably is of the type that assumes the intermediate state in the absence of power being supplied thereto by the driving circuit 6 or when the power level supplied is inadequate; assumes the clear state in the presence of a first electric field input, i.e., an electric field of a first magnitude; and assumes the dark state in the presence of a second electric field input, i.e., an electric field which is of greater magnitude than the first.

Although the preferred embodiment employs the lens 5 in a welding helmet 1, the lens may be used for other eye protection functions or other functions in accordance with the operative principles described herein. As will be appreciated, the lens provides control of the intensity of light transmitted therethrough, for example, to the eyes of a welder. Preferably such transmission is without degradation of the image characteristics of the transmitted light, thus, enabling an object, scene, etc. to be viewed without distortion. Moreover, it will be appreciated that although the lens of the invention preferably is used to protect the eyes of a person, it may be used to control transmission of electromagnetic energy for other purposes as well.

The driving circuit 6 includes a source of electric power, e.g., a storage battery, photovoltaic cell, transformer connection to some other power source (such as that available through an electrical receptacle), etc., and circuitry necessary to establish the requisite electrical field across the liquid crystal cell in the welding lens 5. A sensor or detector 7, which may be part of the driving circuit, is cooperative with the driving circuit to detect the intensity of incident light and to produce an electrical field having a voltage which is analog or step-wise proportional in amplitude to the intensity of such incident light. More particularly, when the intensity of light incident on the sensor 7 is less than that occurring during welding, the driving circuit 6 produces an electric field which energizes or drives the welding lens 5 to the clear state; and when light incident on the sensor 7 is representative of the occurrence of welding (e.g., commencing immediately upon striking of the welding arc represented at 8), the driving circuit 6 produces an electric field which energizes or drives the welding lens 5 to the dark state. An exemplary driving circuit is described in copending U.S. patent application Ser. No. 07/365,167, filed Jun. 12, 1989, the entire disclosure of which is incorporated by this reference. Other driving circuits also may be used and/or designed that perform the various functions energizing the liquid crystal lens in the described manner. Should the driving circuit fail such that power is not provided the welding lens in particular (or that provided is inadequate), the welding lens will assume the intermediate state or shade, as is described in further detail herein.

Using the welding helmet 1, a welder would press a power switch 9 to turn on the driving circuit 6 to energize the welding lens 5 to the clear state; and then welder would place the helmet on his or her head generally aligning the welding lens 5 with the eyes 10. As a result of energizing the welding lens 5 to the clear state, the welder then can see through the welding lens to place the welding tools in proximity to a work piece intended to be welded. Upon the inception of welding, e.g., striking of the welding arc, the sensor 7 detects the same and causes the driving circuit 6 to energize the welding lens 5 to the dark state. The dark state is designed to protect the eyes of the welder from damage due to the electromagnetic emissions, in particular the intense light emitted during welding. In case the driving circuit 6 were to fail during use, the welding lens 5 would preferably promptly assume the intermediate state, which is sufficient to provide a measure of protection to the eyes of the welder until the welding action is terminated. The shield 2 and the filter assembly 3 preferably are adequately strong to protect the face of the welder from particulates possibly emitted during welding; and the shield itself also preferably is not optically transmissive so that it provides protection from electromagnetic energy for the face and eyes of the welder during welding.

Turning to FIG. 2, the features of the welding lens 5 are shown. The welding lens 5 includes a band pass filter 20 and a controllable variable wavelength light transmission controlling device 21 which are in optical series so that light from welding operation, e.g., emitted by a source 8, such as the welding arc, will have to pass through both before reaching the eyes 10 of the welder. Optically, it does not matter which of the filter 20 or device 21 is closer to the welding arc source 8 and which is closer to the eyes 10. However, in the preferred embodiment the band pass filter 20 is placed optically upstream (relative to the eyes 10) of the variable device 21. Since the filter 20 preferably is not dynamic or actively changed, and, therefore, is less subject to damage than the device 21, since it preferably has a hard exterior surface, such as glass or quartz, etc., for strength and durability, and since it preferably blocks transmission of ultraviolet and infrared wavelengths of electromagnetic energy which are known to be damaging to at least some liquid crystal cells and/or materials thereof, this positioning will avoid subjecting the optically active device 21 to unnecessary damage and may increase longevity.

The band pass filter 20 may be a conventional optical band pass filter which transmits light in a prescribed wavelength region and blocks transmission of light (filters out light) in a different wavelength region or regions. For example, referring to the primary colors (red, green and blue), the band pass filter may transmit blue light and partially block (filter) red light and green light. (Preferably the device 21 conversely tends to block much of the blue light and partially to transmit red and/or green light. In any event, the device 21 in the deenergized condition preferably should not transmit efficiently light of the wavelength that is efficiently transmitted by the band pass filter 20; and vice versa.) Preferably the band pass filter 20 substantially blocks transmission of infrared light and ultraviolet light. In one example, the band pass filter 20 has transmission between 500 nanometers (nm) and 600 nm of 30% or more of the incident light; and it has a transmission at 540 nm of about 45% or more. Moreover, such band pass filter may have reduced transmission characteristics tapering substantially toward zero transmission for wavelengths that decrease beyond about 400 nm and that increase beyond about 600 nm.

An example of the transmission characteristics of a band pass filter 20 is represented by curve 20a in FIG. 3. In FIG. 3 the vertical axis represents as a percentage the ratio of light incident on the particular device to that transmitted through the device, such as the band pass filter 20 or the variable device 21, and the horizontal axis represents the wavelength of such light. Curve 20a depicts a maximum transmission of about 20% for light incident on the band pass filter 20 having a wavelength on the order of about 500 nm. Curve 20a also depicts how the amount of light that is transmitted by the band pass filter 20 decreases to various amounts less than about 20% of the incident light as the wavelength of the incident light approaches 400 nm or approaches 600 nm from the peak transmitted wavelength of about 500 nm.

The controllable variable wavelength transmission controlling device 21 is a device that has the ability to control transmission and blocking of light, and under prescribed circumstances to effect such control as a function of the wavelength of the light incident thereon. More particularly, the device 21 is tuned so that in the absence of a power input (hereinafter referred to as the power off or fail mode or state), or under some other circumstance which preferably is predetermined, it will substantially block transmission of light that has a wavelength in the region of that at which light, most preferably maximum light, is substantially passed by the band pass filter 20 during such power off mode. In the illustrated example such wavelength is about 500 nm, as is seen in FIG. 3. Furthermore, the device 21 is operable to a clear state having a maximum transmission of light incident thereon substantially independent of wavelength and to a dark state blocking substantially all of the light incident thereon, thus also being substantially independent of wavelength.

In FIG. 3 curve 21a represents the tuned condition of the device 21 in the power off mode. It can be seen that there is maximum transmission of about 20% of the incident light when that incident light has a wavelength of about 600 nm, and the transmission decreases on either side of that maximum. There is a portion 22 in the graph of FIG. 3 where curves 20a and 21a overlap and encompass a commonly included area (shown by hatching in the figure) representing transmission by both the band pass filter 20 and the variable device 21. That portion 22 indicates that in the power off mode, some light will be transmitted through the welding lens 5; approximately 10% of the incident light which has a wavelength at about 550 nm will be transmitted, and less than 10% of the incident light which has a wavelength other than 550 nm will be transmitted. Since the band pass filter 20 only outputs or transmits through it some of the total incident light energy directed to the welding lens 5 according to the curve 20a of FIG. 2, and since the controllable variable device 21 only transmits a part of the light it receives from the band pass filter 20, e.g., according to the curve 21a, then, in the illustrated example in FIG. 2, the amount of light transmitted or output by the welding lens 5 in the power off mode is the product of the percent transmission by the band pass filter 20 and the percent transmission by the controllable variable device 21. Thus, if the band pass filter transmits about 17% of the incident light at 550 nm and at 550 nm the controllable variable device 21 transmits about 17% of the light received from the 550 nm, then the light output by the welding lens 5 at 550 nm would be I*17%*17%, where I is the intensity of incident light on the welding lens 5; and such light output by the welding lens, of course, would be different for different wavelengths. A total intensity profile of the output of an exemplary welding lens according to the invention is described below with respect to the curve of FIG. 10.

Desirably the characteristics of the band pass filter 20 and of the controllable variable wavelength transmission controlling device 21 are selected such that in the presence of a welding arc the amount of light represented at portion 22 of the graph of FIG. 3 will not injure the eyes 10 of the welder in case there is an accidental power off or power failure occurrence of the driving circuit 6, especially if upon realizing such power off or power failure occurrence the welder relatively promptly terminates the welding operation.

Briefly referring to the graph of FIG. 4, which has the same vertical and horizontal axes representing percent optical transmission and wavelength of incident light respectively, the optical transmission curve 21b for the device 21 during energization by the driving circuit 6 to the clear state is shown relative to the same curve 20a described above with respect to FIG. 3. Such clear state preferably encompasses all area encompassed by the curve 20a, which represents the optical transmission characteristics of the band pass filter 20. Therefore, in the clear state the welding lens 5 will preferably transmit the maximum amount of light of which optical series arrangement of the individual components thereof are capable. If desired, the curve 21b representing the clear state of the device 21 need not overlap the entire curve 20a; for example, there may be only portions which overlap, i.e., are Boolean conjugate. However, the amount of such overlap can be determined as a function of the particular characteristics of the device 21. In the preferred embodiment, though, the device 21 in the clear state is as transparent as possible to visible light substantially independent of wavelength (or at least is sufficiently transparent as to transmit substantially all light received from the filter 20), and such characteristic is evident from the curve 21b. It will be appreciated that in the example presented in FIG. 3, the controllable variable device 21 tends to transmit approximately 25% of the light incident thereon regardless of wavelength (at least in the operating wavelength range of the welding lens 5 as determined by the band pass filter 20 and curve 20a; therefore, the amount of light transmitted by the welding lens 5 in the clear state represented by the graph of FIG. 3 would be about 25% of the light that is received by the device 21 from the band pass filter 20.

No graph is shown for operation of the welding lens 5 in the dark state. In such dark state the band pass filter 20 maintains its optical transmission characteristics which are represented in curve 20a; however, the controllable variable wavelength transmission controlling device 21 is energized to block substantially all light incident thereon substantially independent of wavelength. Therefore, there will be substantially no light transmission by the welding lens 5 during such energization. Moreover, such dark state is produced, as will be described in further detail below, in response to the application of a relatively maximum electric field to the device 21 compared to a lesser field being applied during the clear state and zero field state during the power off mode. Accordingly, switching to the dark state will be relatively fast.

An embodiment of filter assembly 30 for use in the welding helmet 1 is illustrated in FIG. 5. The filter assembly 30 includes the driving circuit 6 and a welding lens 31. The welding lens includes the band pass filter 20 and a controllable variable wavelength transmission controlling device 32, which are cooperatively interrelated to function generally in the manner described above with respect to the filter assembly 3 shown in FIGS. 1 and 2. The device 32 includes a pair of plane polarizers 33, 34 and a surface mode liquid crystal cell 35. The optically upstream polarizer 33, i.e., the one closer to the source of light 8, will be referred to as the polarizer for the device 32, and the polarizer 34, which is at the optically downstream side of the cell 35, sometimes will be referred to as the analyzer, as is conventional. The cell 35 is coupled to the driving circuit 6 for controlled energization thereof as a function of intensity of light incident on the sensor 7. Overall construction and operation of the surface mode liquid crystal cell 35 are described in several of the above-mentioned incorporated patents and are known in the art at this time. As is described in such patents, preferably the axis of the surface mode liquid crystal cell (i.e., the rub direction described further below) is oriented approximately at about 45 degrees relative to the polarization direction of the polarizers 33, 34. This will maximize and optimize utilizing the birefringence characteristics of the surface mode liquid crystal cell.

The lens 31 operates generally in the manner described above for the lens 5; note the discussion regarding operation with respect to the curves and light transmission described with respect to FIGS. 2, 3 and 4. The particularly unique features of the surface mode liquid crystal cell 35 in cooperation with the polarizer and analyzer 33, 34 provide for wavelength dependency during the power off state and for wavelength independent light transmission and darkness during the clear and dark states, as will be described below with respect to FIGS. 6A, 6B and 6C.

The surface mode liquid crystal cell 35 includes a pair of plates 40, 41, usually of glass, plastic or other polymer material, etc., preferably generally transparent to visible light, and positioned generally in parallel planar relationship. The plates 40, 41 define a volume 42 therebetween, which usually is sealed at the edges of the plates, containing liquid crystal material 43. The liquid crystal material 43 preferably is nematic liquid crystal material or operationally nematic liquid crystal material which has the desired optical, alignment, and operational characteristics of nematic liquid crystal. The nematic liquid crystal material has directors or structural alignment characteristics which are influenced by the surfaces 44, 45 of the plates. Those surfaces 44, 45 preferably are pretreated, e.g., by rubbing in parallel direction or by some other means, to cause alignment of the liquid crystal directors with such rub direction, as is known. Moreover, the plates 40, 41, are positioned so that the rub directions thereof are in the same direction or in an opposite direction (sometimes respectively referred to as parallel and anti-parallel). In the absence of an electric field, the liquid crystal structure will tend to align generally in parallel with such rub directions, as is depicted schematically in FIG. 6A.

The cell 35 also has electrodes 46, 47 on the surfaces 44, 45 to apply electric field across the liquid crystal material in the cell, as is conventional. Such electrodes may be indium tin oxide (ITO) or some other suitable electrically conductive optically transparent material. Desirably the cell 35 should be protected from the occurrence of short circuits when relatively high voltage is applied. For this purpose several known techniques may be used. One is to provide insulation between the electrodes and the liquid crystal material; an exemplary insulating material is silicon dioxide. Another technique is to provide relatively large contact areas between the respective electrodes and the electrical distribution system that supplies voltage thereto so that the voltage and, thus, the electric field, is supplied as uniformly as possible over the entire electrodes. Other techniques to avoid short circuits in response to relatively high voltage energization also may be used.

As is seen in FIGS. 6A, 6B and 6C, the plane polarizer 33 and analyzer 34 are crossed, i.e., aligned with the respective axes of polarization or directions of planes of polarization thereof generally at right angle relationship to each other. Therefore, absent the surface mode liquid crystal cell 35, incident light 50 transmitted through the polarizer 33 would be polarized in the plane of polarizer 33, say vertically, as illustrated by the arrow 36, and it would be blocked from transmission through the relatively crossed analyzer 34 which would then be polarized into the plane of the paper, or horizontally, as illustrated by the cross 37.

Intermediate State, Power Off State, Fail State:

In the absence of an electric field, or in the absence of a sufficient electric field, such that the liquid crystal material 43 will be aligned in the manner shown schematically in FIG. 6A, polarized light transmitted through the cell will undergo both optical retardation and color dispersion. Retardation is a function of the equation ##EQU1## where (Δn) is the birefringence or difference between the normal and ordinary indices of refraction of the liquid crystal material; t is the thickness of the layer of liquid crystal material which exhibits the birefringence characteristic, and (λ) is the wavelength of the light. Since, as is seen from Equation 1, retardation is a function of wavelength, different wavelengths will experience different amounts of retardation during transmission through the cell 35. The retardation function is analogous to that provided by a wave plate. As plane polarized light, for example, incident on the cell 35 is transmitted through the liquid crystal material 43, such light will be converted to elliptically polarized light, the direction of the major axis of the ellipse with the extent of ellipticity (i.e., from plane polarized light to circular polarization or ratio of the minor axis to the major axis of the ellipse) being a function of birefringence of the liquid crystal material, thickness of the liquid crystal layer, and wavelength of the light. Thus, the components or magnitudes of the various wavelengths of light that are in the direction of the polarization direction of the analyzer 34 will be different. Therefore, the transmittance of light by the device 32 will vary as a function of wavelength.

The surface mode liquid crystal cell 35 can be tuned with respect to the band pass filter 20 by selecting of liquid crystal material with a particular birefringence characteristic and by selecting the particular thickness of the liquid crystal layer 43 so that the wavelength of light that tends to have the greatest transmittance by the device 32 in the absence of an electric field will not be the same as the wavelength of light that has the greatest transmittance by the band pass filter 20. Thus, an operational transmission curve of the type depicted at 21a in FIG. 3 for different wavelengths of light incident on the device 32 of FIGS. 5 and 6A, can be obtained in the absence of an applied electric field. It will be appreciated, then, that the surface mode cell 35 can be tuned with respect to the band pass filter 20 to provide for the desired shade of the intermediate state for the welding lens 31 relative to the clear and dark states thereof. It also will be appreciated that tuning of the surface mode liquid crystal cell may be achieved by selection of the materials thereof (e.g., according to birefringence characteristics of the liquid crystal material which are, of course, well known), by mechanical structure (e.g., according to the spacing of the surfaces between which the liquid crystal material is contained, e.g., on the order of from several to several tens of microns and especially from about 4-20 microns, especially 5-11 microns), and by electrical input (e.g., the electric field which causes an aligning of liquid crystal structure (directors) with respect to the field and in proportion to the magnitude thereof).

Clear State:

In FIG. 6B the surface mode liquid crystal cell in the controllable variable wavelength transmission controlling device 32 of the lens 31 (FIG. 5) is shown in the clear state. Accordingly, an electric field E₁ of a magnitude suitable to align some of the liquid crystal 43 is applied by the driving circuit 6 via the electrodes 46, 47 across the liquid crystal material 43. The liquid crystal preferably has positive dielectric anisotropy so it will align with the electric field as is illustrated to obtain the described optical result. That liquid crystal near the center portion of the cell between the plates 40, 41 aligns with the field, and that liquid crystal nearer the surfaces 44, 45 of the plates remains generally aligned with the surfaces. Such alignment is shown schematically in FIG. 6B. The thicknesses of the several differently aligned portions of liquid crystal are designated t_(a), t_(b), and t_(c). It will be appreciated that although distinctly aligned portions of liquid crystal material are shown, e.g., parallel or perpendicular to the surfaces 44, 45, it is expected that some liquid crystal will be somewhat otherwise angularly oriented at various boundaries, e.g., at the surfaces 40, 41 and/or at the areas where the differently aligned portions come together to provide, for example, a more or less continuous or smooth transition between those portions.

As is known, the liquid crystal material that is in the center of the cell (having a thickness t_(b)) will not have any significant optical affect on light transmitted therethrough due to alignment of the ordinary axis of the liquid crystal material parallel with respect to the direction of transmission of light 50 through the cell. However, that liquid crystal in the surface layers (having thicknesses t_(a) and t_(c)) is oriented perpendicular to the direction of transmission of light through the cell and, consequently, the cell will exhibit birefringence. Accordingly, light transmission therethrough will vary as a function of the polarization direction of the light, with the effective thickness t of the liquid crystal material exhibiting such birefringence (for use in the above Equation 1) being the sum of the thicknesses of the layers oriented perpendicular to the direction of light transmission, namely the sum of the thickness t_(a) and t_(c).

The birefringence of the liquid crystal material 43 and the magnitude of the electric field E₁ are selected such that the result of Equation 1 corresponds to substantially a 90° rotation of the plane of polarization for all wavelengths of incident light. (E₁ influences Equation 1 indirectly by determining the effective thickness of the birefringent portion of the liquid crystal material, i.e., the thickness t_(a) and t_(c).) As can be seen from Equation 1, the smaller the numerator (Δn*(t_(a) +t_(c))), the smaller the difference in retardation for various wavelengths of light (λ). Consequently, the numerator of Equation 1 is minimized, while still providing for a degree of retardation corresponding to substantially 90° rotation of the plane of polarization of incident light, to minimize color dispersion. A surface mode liquid crystal device operating in such a manner is said to be operating at zero order. As will be discussed more fully below, a device operating at a higher order may still provide for the effective 90° rotation of light for one wave length (such as by rotating it 270°, 450°, etc.) but would have a greater difference in the actual retardations for various wavelengths, thus creating color dispersion. Such a high order operating device may be obtained by increasing the thickness of the portion of liquid crystal material oriented perpendicular to the propagation direction of light through the device.

With the retardation occurring in response to application of the field of magnitude E₁, the surface mode liquid crystal cell 35 is intended to effect retardation that results in rotation by about 90 degrees of the plane of polarization of the incident plane polarized light received from the polarizer 33. Therefore, the light directed from the cell 35 to the analyzer 34 will be transmitted substantially completely by such analyzer.

The just described operation of the surface mode liquid crystal cell 35 is that of the clear state for the lens 31. Since operation in the clear state is at or approximately at zero order at which there is substantially no color dispersion, light transmission through the controllable variable wavelength transmission controlling device 32 will be independent of wavelength.

Moreover, an advantage of using a surface mode liquid crystal cell and driving it to the clear state as well as in the dark state is the substantial uniformity of optical response across the entire liquid crystal cell due to substantial uniformity of thickness of the birefringent layer(s) t, t_(a), and t_(b) when the liquid crystal cell is energized; and this provides for uniformity of the viewed image minimizing the possibility of distortion. Another advantage is the ability to provide some chromatic operation, e.g., at the intermediate state and even to provide for chromatic tuning, and some achromatic operation, e.g., at the clear and dark states (as well as when the liquid crystal cell is driven at levels between the clear and dark states, as is described below with respect to FIG. 10.

Dark State:

Briefly referring to FIG. 6C, the surface mode liquid crystal cell 35 is shown in its fully energized state with the relatively maximum voltage electric field E₂ being applied thereto to align substantially all of the liquid crystal material 43 with respect to the field. As a result, light 50 transmitted through the cell 35 will only experience the ordinary index of refraction of the liquid crystal material and will not experience birefringence; therefore, the birefringence term and the thickness of the birefringent layer term of Equation 1 are zero or near zero. Accordingly, the result of Equation 1 goes to zero, and there will be no retardation of the plane polarized light 50 incident on the cell 35 as such light is transmitted therethrough. Therefore, a substantial amount of light directed from the cell 35 to the analyzer 34 will be blocked by the relatively crossed analyzer 34 allowing only an adequate amount for the welder to safely see the welding area, for example, 0.1% transmission, preferably 0.01% transmission, and possibly even less transmission of light relative to the amount of light incident on the welding lens. Such blocking of light is independent of the wavelength of the light.

The just described operation represents the dark state for the lens 31.

It will be appreciated that the magnitude of the electric field E₂ is greater than the magnitude of the electric field E₁. Therefore, the maximum field is used to drive the lens 31 to the dark state, and, accordingly, the speed of operation will be maximized. Moreover, it will be appreciated that the surface mode liquid crystal cell 35 (especially in combination with the polarizer and analyzer) when in the deenergized or power off mode described with respect to FIG. 6A provides light intensity modulation with respect to wavelength. However, the surface mode liquid crystal cell 35 is used for its light intensity modulation characteristics independent of wavelength in the clear and dark state described operation with respect to FIGS. 6B and 6C.

It also will be appreciated that by varying the voltage of the electric field applied to the surface mode liquid crystal cell 35 between the voltages that provide the clear and clear state and the dark state, there can be obtained a substantially analog variation in the intensity of the transmitted light or analog variation in the shade number of the lens without regard to color. Since the surface mode liquid crystal cell 35 is operated at zero order between the clear and dark states, varying the voltage of the applied electric field will alter the intensity of the light output by the cell 35 independently of color. This operation is described below with respect to the graph of FIG. 10.

As those skilled in the art will appreciate, the foregoing description of operation of the surface mode liquid crystal cell 35 assumes certain optimized circumstances. For example, the axis of polarization of the polarizer 33 and of the analyzer 34 are at least approximately at right angles with respect to each other, and the rub direction of the liquid crystal cell 35 (also referred to as the axis of the surface mode cell 35) and, thus, the deenergized alignment direction of the liquid crystal material 43 therein is at least approximately at 45 degrees with respect to the axes of the polarizer and analyzer so as to provide optimized retardation or wave plate functions. However, those values and/or relationships can be varied, as is known, in which case similar operation will occur, but compensation may have to be provided, e.g. along the lines disclosed in the above-mentioned patents relating to the surface mode liquid crystal cell invention and as is elsewhere described herein and in other literature. Further, the foregoing description presumes that all liquid crystal aligns in the cell 35 either parallel to the surfaces or perpendicular to the surfaces (i.e., parallel to the applied field) and that in the presence of the field E₂ all liquid crystal 43 aligns with the field. In fact this may not be the case due to certain surface energy and surface connection considerations in the liquid crystal cell 35. However, as also is disclosed in the just referenced patents, below, and in the published literature, compensation for the effects of these realities is possible and, in fact, is included in the embodiment which is described below. Nevertheless, it will be appreciated that the principles of the invention envision operation in circumstances without the need for such compensation either in the circumstances or ideal materials or conditions, or where acceptance of a variation in the operation of the lens still provides the desired or adequate optical operational characteristics for a given job.

Multiple Variable Devices Embodiments:

Turning, now, to FIG. 7, a modified embodiment of filter assembly 60 with a welding lens 61 and driving circuit 6 including a sensor 7, is shown. The lens 61 is similar to the lens 31 except that it includes an additional optical stage 62 for further attenuating light, particularly during the dark state. Thus, the lens 61 has three stages, that of the band pass filter 20, that of the variable device 32, and that of the additional optical stage 62.

It is known that polarizers are not perfect optical elements in that the light transmitted by a plane polarizer may include some light that is not polarized in the direction of polarization of the polarizer. Such imperfections therefore may permit some residual leakage of light through the lens 31. Further residual leakage of light through the lens 31 may occur due to the imperfections in the surface mode liquid crystal cell 35 and misalignments of the cell relative to the polarizer and analyzer as well as the reality of alignment characteristics of the liquid crystal in the cell, e.g., tilt angle proximate the surfaces, continuity of alignment between the surface and central areas in FIG. 6B rather than the exemplary abrupt discontinuity between the different aligned portions of liquid crystal material in the cell 35 of FIG. 6B, and actual or near impossibility of aligning all of the liquid crystal at the surfaces in the cell 35 of FIG. 6C.

In the lens 61 the residual light that may leak from the band pass filter 20 and the controllable variable wavelength transmission controlling device 32 in the dark state is represented by 50' (when the lens is in the clear or intermediate state light also is transmitted from the device 32 to the further stage 62). That light is directed to the additional stage 62, which includes a further liquid crystal cell 63 and plane polarizer 64. The further liquid crystal cell 63 may be a surface mode liquid crystal cell, a twisted nematic liquid crystal cell or a dyed liquid crystal cell. Alternatively, the further liquid crystal cell 63 may be another type of device that can be activated selectively to alter effectively the plane of polarization (or to effect retardation) of light transmitted therethrough as a function of a prescribed input, e.g., the electric field supplied by the driving circuit 6.

The additional stage 62 in the lens 61 is intended further to reduce transmission of light through the lens when in the dark state. Depending on the design of the lens 61, the additional stage may or may not contribute to darkening of the lens during the clear and intermediate states. For example, the orientation of the polarizer 64 relative to the orientation of the polarizer 34 may be varied to reduce transmission during clear and/or intermediate states, etc., or to avoid such reduction, e.g., to transmit plane polarized light that is transmitted by the polarizer 34.

Stage 62 having a Twisted Nematic Liquid Crystal Cell:

In the case that the further stage 62 includes a further liquid crystal cell 63 which is a twisted nematic liquid crystal cell, such cell is positioned in optical alignment with the device 32. The polarizer 64 would be oriented preferably generally crossed relative to the polarizer 34. The cell 63 preferably is energized simultaneously with the cell 35 by the driving circuit 6 when the driving circuit is operative to drive the filter assembly to the dark state; otherwise the cell 63 would be deenergized.

Therefore, in the power off intermediate state of the lens 61, polarized light according to the area under the curve portion 22 (FIG. 3) from the polarizer 34 is plane polarized. The plane of polarization of that polarized light is rotated 90 degrees by the twisted nematic liquid crystal cell 63, and the light then is transmitted through the polarizer 64 for viewing by the welder's eyes 10. Since the polarizer 64 is crossed relative to the polarizer 34, and since the twisted nematic liquid crystal cell 63 rotates the plane of polarized light received from the polarizer 34 by 90 degrees, the further stage 62 does not significantly attenuate the light from the polarizer 34 to the eyes 10 of the welder. The same type of operation occurs during the clear state as the device 32 transmits substantially all light received from the band pass filter 20, and that light then is transmitted by the second stage.

When the filter assembly 60 is switched to the dark state, the driving circuit 6 supplies electric field to both the surface mode liquid crystal cell 35 substantially to block light through the lens 61, although possibly allowing a small amount of residual light 50' to be emitted as plane polarized light from the polarizer 34; and the twisted nematic liquid crystal cell 63 is energized by the driving circuit 6 so that such cell no longer rotates the plane of the polarized light 50' incident thereon. Such polarized light 50' then will impinge on the relatively crossed polarizer 64 and will be further blocked thereby, thus reducing the possiblity that significant residual light would leak from the lens 61. As is mentioned elsewhere in this and other embodiments the dark state for a welding lens still allows some transmission so a welder can see while welding. That this transmission occurs can be due to leakage by the polarizers, alignment of the components, e.g., surface mode liquid crystal cell, twisted nematic liquid crystal cell, polarizer(s), wave plate(s), etc. Full light blocking also may be possible in the dark state and indeed desirable in some applications of the features of the invention.

Stage 62 having a Dyed Liquid Crystal Cell:

In the case of the further stage 62 using a liquid crystal cell 63 that is a dyed nematic liquid crystal cell, such cell is positioned in optical alignment with the device 32. The polarizer 64 would be eliminated. A dyed liquid crystal cell usually is formed by a pair of parallel transparent plates that are rubbed or otherwise treated to obtain alignment of liquid crystal material in parallel therewith, and the two plates are oriented in parallel planar relation with the rub directions in parallel, i.e., in the same or opposite directions. The liquid crystal material between the plates has in solution or mixture therewith pleochroic dye that has a polarizing function when the liquid crystal material is aligned in parallel with the mentioned rub direction. In the presence of an electric field the liquid crystal material and dye align with respect to the field to reduce such polarizing effect.

Therefore, it will be appreciated that using a dyed liquid crystal cell for the cell 63, the driving circuit 6 would energize such cell when the lens 61 is to be operated in the clear or intermediate state. However, when it is desired to operate the lens 61 in the dark state, the dyed cell 63 would be deenergized thereby allowing the liquid crystal and dye therein to assume the relaxed alignment with the mentioned rub directions. If the rub directions are such that the effective polarizing action by the dyed liquid crystal cell 63 is crossed relative to the polarization axis or direction of the polarizer 34, reduction in residual light 50' in the dark state will be achieved. Although the dyed cell 63 would switch to the dark state in response to relaxation, and, therefore, would not be as fast operating as the surface mode cell 35, such reduced speed may not be significant in circumstances where the light attenuation to the dark state provided by the surface mode cell 35 in the variable device 32 is adequately dark to provide adequate protection for the amount of time until the dyed cell 64 relaxes to its own dark condition.

Stage 62 having a Surface Mode Liquid Crystal Cell:

The liquid crystal cell 63 may be a surface mode liquid crystal cell, and the operation thereof is substantially the same as the operation of the surface mode liquid cell 35. The surface mode cell 63 may be identical to the cell 35; it may be tuned to the same extent as the surface mode cell 35 insofar as the thickness, birefringence characteristics, energization characteristics, retardation characteristics, etc. are. As was described above, it is desirable that the rub axis of the surface mode cell is oriented approximately at 45 degrees relative to the polarization direction of the polarizer 34 and that the polarization direction of the output polarizer (analyzer) 64 is crossed relative to that of the polarizer 34. Therefore, in the power off state or intermediate shade, the further stage 62 will contribute to darkening of the lens 61 to some extent; that extent would depend on various alignment and tuning conditions and to natural losses in the optical elements as will be evident from the description herein. If, however, alignment of the various components were perfect and there were no natural losses in the optical system of the further stage 62, then the amount of contribution to darkening of the lens in the intermediate state/power off state could be made negligible in that the transmission curve would be similar to curve 21a in FIG. 3. Similar considerations would apply with respect to operation of the lens 61 in the clear state during which both the surface mode cell 35 and the surface mode cell 63 would be energized substantially to maximize light transmission therethrough. In such case the polarizer 64 would be crossed relative to the polarizer 34, the rub direction or axis of the surface mode cell 63 would be at 45 degrees relative to the polarization direction of the polarizer 34, and the field applied to the surface mode cell 63 would be adequate to effect rotation of the plane of polarization of the incident light 50' by 90 degrees substantially independent of wavelength.

However, in the dark state the driving circuit 6 drives the two surface mode liquid crystal cells 35, 63 at relatively maximum field to obtain liquid crystal alignment approximately as in FIG. 6C to minimize transmission. In particular, the residual light 50' is plane polarized, and the fully energized surface mode cell 63 tends not to rotate the plane of polarization of that light. Therefore, the plane of polarization thereof is crossed relative to the polarizer 64, and, accordingly, the polarizer 64 tends to block transmission of a substantial portion (possibly all) of such residual light.

Compensated Multiple Stage Surface Mode Liquid Crystal Lens 70:

In FIG. 8 is shown at 70 a modified form of the filter assembly, which includes the filter assembly 60 (of FIG. 7) and also includes two wave plates (designated 75 and 76 in FIG. 8 and described further below) to compensate the surface mode liquid crystal cells 35', 35" for residual birefringence that occurs due to the inability to align all of the liquid crystal material with respect to a maximum applied electric field intended for the dark state. Such inability is due to surface energy and/or anchoring of the liquid crystal material at the respective surfaces of the cell plates. Alternatively, it may be possible to align substantially all or even all (in an ideal circumstance) of the liquid crystal material with respect to a field; but to do so would require a field of greater magnitude than the magnitude of a field that would align less than all but nevertheless an adequate amount of the liquid crystal material. Therefore, use of the wave plates described below will reduce the magnitude of electric field required for effective operation of the filter assembly 70.

Fundamentally, operation of the welding lens 71 of the filter assembly 70 is the same as that described above with respect to the filter assembly 60 and welding lens 61 employing two surface mode liquid crystal cells 35' and 35", as is illustrated in FIG. 7 to achieve the intermediate, clear and dark states. The liquid crystal cells 35' and 35" are analogous to the cells 35 and 63 in FIG. 7; and preferably the liquid crystal cells 35' and 35" are the same. Thus, primed and double primed reference numerals designate respective parts that are the same as or similar to those designated by the same unprimed reference numeral.

The welding lens 71 has three stages, including the band pass filter 20 as the first stage, and two variable devices stages, respectively including a first compensated surface mode liquid crystal stage constituting a controllable variable wavelength transmission controlling device 72, and a second compensated surface mode liquid crystal stage constituting a further controllable variable wavelength transmission controlling device 73. A transparent cover glass 74 at the downstream end of the lens 71 separate the eye 10 from the other parts of the lens for protection of the lens and/or of the eye. Each device 72, 73 preferably is optically the same (although there may be differences, depending on the desired optical result consistent with the disclosure hereof). Each includes a wave plate 75, 76, respectively, which together with a compensating, corresponding or related alignment of the polarizers 33' and 34" provides for compensation for the residual birefringence of the surface mode liquid crystal cells mentioned above.

Briefly, the first controllable variable wavelength transmission controlling device 72 includes a polarizer 33', an analyzer 34', a surface mode liquid crystal cell 35', and the mentioned wave plate 75, which preferably is a quarter wave plate for green light, i.e., it provides quarter wave retardation for green polarized light incident thereon, as is well known. Green light is approximately in the center of the visible light spectrum and it is known to provide wave plate compensation for green light when it is possible that some compensation also is desired for other wavelengths in the visible spectrum as well as green. If desired, though, the wave plate 75 may provide quarter wave retardation for other wavelength(s). To provide the mentioned compensation for residual birefringence and to provide the optical operation described above for the lens 31, for example, alignment of the various elements of the first device 72 relative to a reference direction of "horizontal" is, as follows: The polarizer 33' direction of polarization is -10 degrees; the axis of the wave plate 75 is 90 degrees; the axis/rub direction of the surface mode liquid crystal cell 35' is 45 degrees; the polarization direction of the polarizer 34' is 90 degrees. Similarly, the alignment of the various elements of the second controllable variable wavelength transmission controlling device 73 relative to the mentioned horizontal direction is, as follows: The polarizer 34" direction of polarization is 90 degrees; the axis/rub direction of the surface mode liquid crystal cell 35" is -45 degrees; the axis of the wave plate 75 is 90 degrees; the polarization direction of the polarizer 33" is 10 degrees. It will be seen that the devices 72, 73 preferably are identical and oppositely positioned for convenience of manufacturing.

Operation of the filter assembly 70 is similar to the operation of the filter assembly 60. The primary difference is that in the lens 71 the orientation of one polarizer of each device 72, 73 is at plus or minus 10 degrees from the reference axis, and the wave plate in combination with such polarizer arrangement compensates for the residual birefringence of the respective liquid crystal cells 35', 35" in a manner that is described in detail in the above-mentioned patents which relate to surface mode liquid crystal cells. For example, the polarizer 33' plane polarizes the incident light thereon, and the relationship of the axial alignment of the polarizer and the wave plate 75 converts such plane polarized light to elliptically polarized light. The surface mode liquid crystal cell 35', especially when operated in the clear and dark states then tends to convert such light to linearly polarized light which is either blocked or transmitted by the analyzing polarizer 34'.

In the lens 71 of FIG. 8, the band pass filter 20 may be a Balzers welding filter or some other band pass filter having the characteristics described herein, the polarizers 33', 34', 33" and 34" cut polarizers, and the wave plates 75, 76 cut wave plates; and the various elements may be adhered together with optical epoxy adhesive material.

Briefly referring to the driving circuit 6 used in the several embodiments hereof, such circuit may be made of conventional parts operative in the manner described herein. In one embodiment, though, it is preferred that the circuit include a multiple stage voltage level output capability which is operative to provide relatively high voltage and electric field to the surface mode cells 35', 35", for example, of FIG. 8, immediately upon switching to the dark state to maximize the speed of such switching; after the initiation of such switching, for example, a few microseconds or milliseconds thereafter, the circuit would reduce the voltage, electric field and, thus, the power draw on the circuit battery or other supply to a level that is adequate to maintain the dark state. As was mentioned above, exemplary circuits for carrying out such operation is disclosed in the respective above-identified patent applications.

As was mentioned above, the surface mode liquid crystal cells 35 and 63 in the filter assembly 60 or the surface mode liquid crystal cells 35', 35" in the filter assembly 70 can be tuned to have the same optical, electrical, etc., characteristics, e.g., each having identical transmission curves along the lines of curves 21a, 21b of FIGS. 3 and 4. However, it also is possible that the tuning of such two surface mode liquid crystal cells 35, 63 or 35', 35" can be different. For example, the transmission curve of each may be adjusted to be substantially the same as the curve 21b of FIG. 4 when energized to the clear state. However, the surface mode liquid crystal cells may be tuned so that in the fail state or power off state the transmission curves thereof are different, in fact, preferably are exclusive of each other and also of the transmission curve of the band bass filter. An example of the optical transmission results this arrangement is presented by the transmission curves 80, 81 in the graph of FIG. 9. Curve 80, 81 represent, respectively, the transmission characteristics for the pair of cell 35, 63 or the pair of cells 35', 35". Curve 82 represents the fixed transmission characteristic of the band pass filter 20. The curves 80, 81, 82 are mutually exclusive. This is possible by tuning the surface mode variable transmission devices 72, 73, for example, by appropriate respective selections of liquid crystal material in each with particular birefringence characteristics, thickness of such liquid crystal cells, angular relationships of the respective polarizers used in conjunction with such liquid crystal cells, characteristics of the wave plates used with such liquid crystal cells, etc.

In the just described embodiment of filter assembly 70 according to the graph of FIG. 9, operation of the filter assembly would be as follows. In the clear state, both liquid crystal cells 35', 35" would be energized sufficiently to cause maximum or substantially maximum transmission of light by the lens 71. In the dark state, maximum energization of the liquid crystal material would occur to provide a fast response to obtain a minimum transmission condition, as was described above. In the power off or fail state, though, since the transmission curves 80, 81, 82 are mutually exclusive, no light should be transmitted through the lens assembly 60, 70, and, therefore, it is possible that the power off state may be as dark or even darker than the dark state.

For the example of welding lens 71 of FIG. 8, though, the clear state may be obtained by electric field applied to each of the liquid crystal cells 35', 35" at a voltage of about 3 or 4 volts. For such example, too, the dark state may be obtained at a voltage of about 18 volts. The range between maximum transmission and minimum transmission by the welding lens 71 may be in the described example from about 5.18% (of the incident light intensity) transmission to about 0.0139% transmission, respectively. These numbers are exemplary, and it will be appreciated that larger or smaller values may be obtained depending on the characteristics of the respective components of the welding lens, relative alignment of the components, tuning, energization, etc. Three different welding lenses made according to the invention like the welding lens 71 illustrated and described with respect to FIG. 8 have demonstrated shade number characteristics of shade 4 in the clear state and shade 10 in the dark state; shade 4 in the clear state and shade 11 in the dark state; and shade 6 in the clear state and shade 12 in the dark state, respectively. Power off state was darker than the clear state and brighter or clearer than the dark state. Without the compensation provided by the wave plates and the associated alignment of the polarizers 33', 33", it is possible that the same darkness or dark shade number as the compensated welding lens 71 does at energization of 18 volts may be obtained, but a larger electric field would be needed, e.g., as much as 50 volts or possibly more.

The order in which the band pass filter 20 and variable transmission controlling device or devices 21 are placed in the optical path from the source 8 to the eyes 10 is not critical to operation. Preferably, though, the band pass filter 20 is optically upstream of the liquid crystal cell(s) to tend to block ultraviolet and infrared energy therefrom. Preferably, though, when the lens assembly uses two liquid crystal stages, those stages, regardless of the order thereof, should be adjacent each other to optimize use of and cooperation between the plane polarizers thereof, for it is possible that transmission of light through the band pass filter would degrade the polarization of the transmitted light.

Briefly referring to FIG. 10, a graph 90 includes a curve 91 depicting light transmission by the welding lens 71 in the filter assembly 70 of FIG. 8. On the vertical axis is shown the transmission T in percent of the incident light on the welding lens 71 which is transmitted as output light by the welding lens. On the horizontal axis is the magnitude of prescribed input to both of the surface mode liquid crystal cells 35', 35", in this case the prescribed input being electric field and the magnitude indicated is in increasing voltage from right to left. The number values beneath the horizontal prescribed input axis may be actual voltage or may be normalized values represented of increasing voltage from left to right as viewed in FIG. 10.

It will be seen from the curve 91 in the graph 90 that at zero input to the liquid crystal cells 35', 35", transmission by the welding lens 71 (light output therefrom) is at about 0.25% of the incident light, as is seen at 92 in FIG. 10. However, when the voltage of the electric field reaches a value (or normalized value) such that there is a peak in the transmission curve 91, i.e., at 93 in FIG. 10, the welding lens 71 is in the clear state transmitting about 5% of the incident light. The amount of transmission by the welding lens 71 then decreases from point 93 toward the area 94 of the curve 91 where the dark state occurs. The greater the voltage of the applied field in the area 94 of the curve 91, the darker will be the lens. However, between the point 93 and the area 94 of the curve there is a substantially linear portion 95 (although linearity is not necessary) where transmission decreases substantially directly proportionally to the applied prescribed input (or the normalized value thereof). Between the clear state of the welding lens 71 represented at point 93 on the curve 91 and the dark state represented at the area 94, the lens operates at zero order and, therefore, light attenuation or modulation thereby is independent of the color (wavelength) of the light. Thus, such operation of the lens 71 is achromatic in the portion 95 of the curve 91. Therefore, light attenuation or modulation by the lens as the voltage of the applied electric field varies between the voltages required for the clear and dark states, respectively, will be an analog function of the applied voltage without regard or at least substantially without regard to color of the incident (or transmitted) light.

Although the above described analog operation of a welding lens or other optical device according to the invention to provide light modulation function along curve portion 95 in FIG. 10 independent of wavelength is a feature of the invention, according to the preferred embodiment the welding lens would have three distinct states. Such states would be a function of three distinct inputs thereto, two of which would be a direct function of the amount of ambient light to which the sensor 7 and driving circuit 6 are subjected and one of which is the fail circumstance. Thus, there would be a clear state in response to an input (preferably a relatively minimum input), a dark state in response to a relatively larger input, and a third state that occurs upon failure of power to the welding lens, as are described in detail elsewhere herein.

It will be appreciated that although several embodiments have been described herein, the various features disclosed in one embodiment and/or drawing figure, may be employed in the other embodiments and/or drawing figures.

Further, although several embodiments have been illustrated and described, such illustrations and descriptions are intended to be exemplary, and it will be appreciated that the scope of the invention is intended to be limited only by the following claims and the equivalents thereof.

Statement of Industrial Application

In view of the foregoing, it will be appreciated that the present invention provides apparatus for protecting the eyes of an individual. 

The embodiments of the invention in which an exclusive property or privilege is claimed are, as follows:
 1. A light transmission control device, comprisinga. band pass filter means for transmitting visible light of a prescribed wavelength and for blocking transmission of visible light of a different prescribed wavelength, and b. variable optical filter means for controllably transmitting light of a visible wavelength, and c. wherein said band pass filter and variable optical filter are cooperatively related to provide at least three different light transmitting conditions, including a maximum transmission, a minimum transmission, and a third transmission.
 2. The device of claim 1, wherein said variable optical filter means is operative in the absence of a prescribed input to cooperate with said band pass filter means to provide such third transmission.
 3. The device of claim 2, wherein said variable optical filter means is operative in the presence of a small prescribed input to cooperate with said band pass filter means to provide said maximum transmission and in the presence of a maximum prescribed input to cooperate with said band pass filter means to provide said minimum transmission.
 4. A liquid crystal lens assembly for protecting the eyes, comprisinga. a band pass filter for transmitting visible light of a given wavelength and for blocking transmission of visible light of a different wavelength, and b. a liquid crystal device in optical serial relation with said band pass filter,said liquid crystal device having variable visible light transmitting conditions as a function of an application of an electric field thereto, said liquid crystal device being tuned for operation in the absence of an electric field to transmit some light and to block some light at the wavelength transmitted by said band pass filter, said liquid crystal device being responsive to application of a minimal electric field to be tuned to transmit substantially a maximum of light incident thereon, and said liquid crystal device being responsive to application of a larger electric field to block transmission of substantially all light incident thereon.
 5. The assembly of claim 4, wherein said liquid crystal device comprises a surface mode liquid crystal cell.
 6. The assembly of claim 4, wherein said liquid crystal device comprises a twisted nematic liquid crystal cell.
 7. The assembly of claim 4, wherein said liquid crystal device comprises a liquid crystal cell with a pleochroic dye therein, wherein said dye tends to absorb light at the wavelength transmitted by said band pass filter as a function of the alignment of said dye.
 8. The assembly of claim 4, wherein said liquid crystal device comprises a plurality of polarizer means for selectively transmitting polarized light as a function of the direction of polarization of said polarizer means, said polarizer means being in optical serial relation, and a liquid crystal means positioned optically in serial relation between said polarizer means for changing the direction of polarization of light transmitted through said first polarizer means as a function of the electric field.
 9. The assembly of claim 8, wherein said liquid crystal means comprises a twisted nematic liquid crystal cell.
 10. The assembly of claim 8, wherein said liquid crystal means comprises a twisted nematic liquid crystal cell.
 11. The assembly of claim 8, wherein said liquid crystal means is operative based on optical retardation.
 12. The assembly of claim 8, wherein said liquid crystal means is a surface mode liquid crystal cell.
 13. Apparatus for controlling transmission of electromagnetic energy which has a plurality of visible wavelengths and is incident thereon, comprisinga. band pass filter means for transmitting at least some said electromagnetic energy incident thereon at at least one wavelength and for filtering at least some electromagnetic energy at at least another wavelength, and b. a controllable optical device in optical series with said band pass filter means, said controllable optical device being able to assume at least three different operational modes includes,i. a first said mode providing substantial transmission of said electromagnetic energy at the wavelength transmitted by said band pass filter means, ii. a second said mode providing filtering of a substantial part of said electromagnetic energy transmitted by said band pass filter means, and iii. a third said mode providing filtering of at least some of said electromagnetic energy at the wavelength transmitted by said band pass filter means.
 14. The apparatus of claim 13, further comprising a further controllable optical device in optical series with said band pass filter means and said controllable optical device, said further controllable optical device being able to assume at least two different operational modes, includingi. a first said mode providing substantial transmission of such electromagnetic energy at the wavelength transmitted by said band pass filter means, and ii. a second said mode providing filtering of substantially all of the electromagnetic energy transmitted by said band pass filter means.
 15. The apparatus of claim 14, wherein said controllable optical device when in said second operational mode thereof has an optical leakage characteristic, and wherein said further controllable optical device when in said second operational mode thereof is operative to block transmission of substantially all of the electromagnetic energy transmitted by said controllable optical device in said second operational mode.
 16. The apparatus of claim 14, wherein said further controllable optical device when in said second operational mode thereof has an optical leakage characteristic, and wherein said controllable optical device when in said second operational mode thereof is operative to block transmission of substantially all of the electromagnetic energy transmitted by said further controllable optical device in said second operational mode.
 17. The apparatus of claim 14, wherein said further controllable optical device has a third operational mode providing filtering of at least some of said electromagnetic energy at the wavelength transmitted by said band pass filter means.
 18. The apparatus of claim 17, wherein said controllable optical device and said further controllable optical device are characterized in that said third operational mode occurs in the absence of a prescribed input.
 19. The apparatus of claim 18, wherein said controllable optical device and said further controllable optical device are characterized in that said second operational mode occurs in the presence of a high level of said prescribed input and said first operational mode occurs in the presence of a prescribed input at a level that is between the absence of said prescribed input and said high level of said prescribed input.
 20. The apparatus of claim 13, said second mode providing filtering of all of the electromagnetic energy transmitted by said band pass filter means.
 21. The apparatus of claim 13, said third mode providing filtering of all of the electromagnetic energy transmitted by said band pass filter means.
 22. The apparatus of claim 13, said third mode providing filtering of only some of the electromagnetic energy transmitted by said band pass filter means.
 23. The apparatus of claim 17, wherein the third operational mode of said further controllable optical device provides filtering of only some of said electromagnetic energy at the wavelength transmitted by said band pass filter means.
 24. The apparatus of claim 17, wherein the third operational mode of said further controllable optical device provides filtering of all of said electromagnetic energy at the wavelength transmitted by said band pass filter means.
 25. The apparatus of claim 13, further comprising circuit means for operating said controllable optical device to provide said control of transmission.
 26. A welding helmet comprising a shield means for protecting the face of an individual, an opening in said shield means and apparatus positioned in said opening to provide variable eye protection for the individual, said apparatus being operative for controlling transmission of electromagnetic energy which has a plurality of visible wavelengths and is incident thereon and comprisinga. band pass filter means for transmitting at least some said electromagnetic energy incident thereon at least one wavelength and for filtering at least some of said electromagnetic energy at least another wavelength, and b. a controllable optical device in optical series with said band pass filter means, said controllable optical device being able to assume at least three different operational modes including,i. a first said mode providing substantial transmission of such electromagnetic energy at the wavelength transmitted by said band pass filter means, ii. a second said mode providing filtering of a substantial part of said electromagnetic energy transmitted by said band pass filter means, and iii. a third said mode providing filtering of at least some of said electromagnetic energy at the wavelength transmitted by said band pass filter means.
 27. An eye protection device for protecting the eyes of a welder or the like, comprising a support for supporting a variable protective lens in position to protect said eyes, and a variable protective lens comprising apparatus operative for controlling transmission of electromagnetic energy which has a plurality of visible wavelengths and is incident thereon, comprisinga. band pass filter means for transmitting at least some said electromagnetic energy incident thereon at least one wavelength and for filtering at least some of said electromagnetic energy at least another wavelength, and b. a controllable optical device in optical series with said band pass filter means, said controllable optical device being able to assume at least three different operational modes including,i. a first said mode providing substantial transmission of said electromagnetic energy at the wavelength transmitted by said band pass filter means, ii. a second said mode providing filtering of a substantial part of said electromagnetic energy transmitted by said band pass filter means, and iii. a third said mode providing filtering of at least some of said electromagnetic energy at the wavelength transmitted by said band pass filter means.
 28. Device for controlling transmission of visible light energy which has a plurality of wavelengths and is incident thereon, comprisinga. band pass filter means for transmitting at least some of said light energy in the green area of the spectrum and for blocking transmission of most of the light in the other visible areas, ultraviolet area, and infrared area of the spectrum, and b. electronically controlled variable optical filter means for controllably transmitting light of a wavelength, c. said electronically controlled variable optical filter means being operational in the absence of a prescribed input to filter light energy in the green area of the spectrum.
 29. The device of claim 28, wherein said optical filter means controllably transmits light as a function of tuning in response to a prescribed input.
 30. The device of claim 28, wherein said optical filter means is operative in the presence of a small prescribed input to provide maximum transmission by the device.
 31. The device of claim 30, wherein said optical filter means is operative in the presence of a relatively maximum prescribed input to provide minimum transmission by the device.
 32. The device of claim 28, wherein said optical filter means is operative in the presence of a maximum prescribed input to provide minimum transmission by the device.
 33. The device of claim 28, wherein said optical filter means comprises a liquid crystal cell which operates on the principle of optical retardation.
 34. The device of claim 33, wherein said optical filter means comprises a surface mode liquid crystal cell.
 35. Device for controlling transmission of light energy which has a plurality of wavelengths incident thereon, comprisinga. band pass filter means for transmitting at least some of least one wavelength of said light energy and for filtering at least some of at least one other wavelength of said light energy, b. electronically controlled variable optical filter means for controllably transmitting light of a wavelength in response to a prescribed input thereto, and c. said electronically controlled variable optical filter means in the absence of a prescribed input being operative to transmit at least some of at least one wavelength of said light energy incident thereon and to filter at least some of at least one wavelength of said light energy incident thereon.
 36. The device of claim 35, wherein said optical filter means operates achromatically in the presence of a prescribed input.
 37. The device of claim 35, wherein said band pass filter means and optical filter means are cooperatively related to provide at least three different light transmitting modes, including a maximum transmission, a minimum transmission and a third transmission.
 38. The device of claim 36, wherein said optical filter means is operative in the presence of a small prescribed input to provide maximum transmission by the device.
 39. The device of claim 36, wherein said optical filter means is operative in the presence of a maximum prescribed input to provide minimum transmission by the device.
 40. The device of claim 37, wherein said optical filter means is operative in the absence of a prescribed input to provide said third transmission.
 41. The device of claim 36, wherein said optical filter means comprises a liquid crystal cell which operates on the principle of optical retardation.
 42. The device of claim 41, wherein said optical filter means comprises a surface mode liquid crystal cell.
 43. The device of claim 35, wherein said optical filter means is operative in the presence of a relatively small prescribed input to provide maximum transmission by the device, is operative in the presence of a maximum prescribed input to provide minimum transmission by the device and is operative in the presence of a prescribed input at a level between the maximum and the minimum input levels to provide transmission by the device at a level between the maximum and the minimum transmission.
 44. The device of claim 43, wherein said optical filter comprises a liquid crystal cell which operates on the principle of optical retardation.
 45. The device of claim 44, wherein said optical filter comprises a surface mode liquid crystal cell.
 46. The device of claim 35, wherein said optical filter means is operative in the presence of a small prescribed input to provide maximum transmission by the device, is operative in the presence of a maximum prescribed input to provide minimum transmission by the device and by varying the prescribed input between the maximum and the minimum level will vary the transmission of the device.
 47. The device of claim 46, wherein said optical filter comprises a liquid crystal cell which operates on the principle of optical retardation.
 48. The device of claim 47, wherein said optical filter comprises a surface mode liquid crystal cell. 